High brightness solid state illumination system for fluorescence imaging and analysis

ABSTRACT

A solid state illumination system is disclosed, wherein a light source module comprises a first light source, comprising an LED and a phosphor layer, the LED emitting a wavelength λ 1  in an absorption band of the phosphor layer for generating longer wavelength broadband light emission from the phosphor, Δλ PHOSPHOR , and a second light source comprising a laser emitting a wavelength λ 2  in the absorption band of the phosphor layer. While operating the LED, concurrent laser pumping of the phosphor layer increases the light emission of the phosphor, and provides high brightness emission, e.g. in green, yellow or amber spectral regions. Additional modules, which provide emission at other wavelengths, e.g. in the UV and near UV spectral bands, together with dichroic beam-splitters/combiners allow for an efficient, compact, high-brightness illumination system, suitable for fluorescence imaging and analysis.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to co-pending U.S. patent application Ser. No. ______, filed May ______, 2013, entitled “High Brightness Illumination System and Wavelength Conversion Module for Microscopy and Other Applications”, which claims priority from U.S. Provisional patent application Ser. No. 61/651,130, filed May 24, 2012, both of which are incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

This invention relates to high brightness solid state illumination systems, particularly illumination systems for fluorescence imaging and analysis.

BACKGROUND

High radiance illumination sources are required for fluorescence imaging and analysis, including fluorescence microscopy. Some applications require broadband or white light illumination. Other applications require relatively narrow band illumination of a particular wavelength range in the ultraviolet (UV), visible or infrared (IR) spectral region.

For example, conventional microscopy illumination systems typically utilize short arc lamps such as high pressure mercury, metal halide, and xenon lamps. These lamps are capable of very high radiance and are suitable sources for direct coupled illumination systems, as well as light guide coupled illumination systems, e.g. using a liquid light guide or a fiber light guide. Nevertheless, it is recognized that there are a number of problems associated with conventional lamp technologies, such as short lifetime, temporal variation of the output power, high voltage operation (typically kilovolts are required to strike the lamp), and use of mercury. The latter is now seen as an environmental hazard and subject to regulations to limit use in numerous countries throughout the world.

Solid state light lighting technology has progressed significantly in recent years and some high brightness light sources using solid state Light Emitting Devices (LEDs), e.g. light emitting diodes, are now available that can potentially provide sufficiently high radiance, broadband illumination for replacement of conventional arc lamps. Solid state LED light sources can offer advantages over conventional arc lamps, such as, much improved lifetime, lower cost of ownership, lower voltage operation, lower power consumption (enabling some battery operated portable devices), and freedom from mercury. Additionally LED light sources can be readily controlled electronically, by modulating the current or voltage driving the device, which allows for fast switching and intensity control through the LED driver, which can be a significant advantage in many applications.

Nevertheless, despite technological advances in LED technology, high brightness LED light sources are not available to cover all wavelengths required for illumination systems for fluorescence imaging and analysis. In particular, the output of LED devices still do not match the radiance of traditional arc-lamps in some regions of the visible spectrum, especially in the 540 nm to 630 nm spectral band, i.e. in the green/yellow/amber range of the visible spectrum. The solid state lighting industry refers to this issue as the “green gap”. Emission in this region of the spectrum is fundamentally limited by the lack of availability of semiconductor materials having a suitable band gap to produce light of the required wavelength.

This is a particular problem for fluorescence imaging and analysis which may, for example, require illumination of a biological sample with a relatively narrow band of illumination of a particular wavelength that is absorbed by a selected fluorophore or marker in the substance under test.

For example, a traditional fluorescence illumination system, e.g. for fluorescence imaging or microscopy, comprises a short arc mercury lamp which provides light emission having spectral peaks near 365 nm, 405 nm, 440 nm, 545 nm and 575 nm. Standard fluorophores that are commonly used for fluorescence imaging and analysis are selected to have absorption spectra having peaks optimized to match these lamp emission peaks. To replace a standard mercury lamp illuminator with a LED based illuminator, it is desirable to be able to provide emission at the same wavelengths and with a comparable output power. There are suitably powerful LEDs that are commercially available for emission at 365 nm, 405 nm, 440 nm. However, in view of the “green gap” mentioned above, there are currently no single color, high brightness LEDs commercially available for emission at 545 nm and 575 nm.

It is well known in the art of LED lighting and illumination to use LEDs in combination with luminescent materials, i.e. fluorescent materials or phosphors, to generate light of wavelengths that are outside the range emitted directly by the LEDS, i.e. by wavelength conversion. In particular, a UV or blue light emitting LED may be combined with a remote or direct die-contact phosphor layer or coating to obtain broadband light emission of a desired color temperature. For example, a blue light emitting diode or diode array with an emission peak in the range between 445 nm and 475 nm is combined with a phosphor layer comprising particles of Ce:YAG (cerium doped yttrium aluminum garnet) suspended in an encapsulant material such as silicone, which is deposited directly on the LED. The blue light from the LED is absorbed by the phosphor and generates a broadband green/yellow/amber light which combines with the scattered blue light to produce a spectrum that provides the perception of white light. The overall brightness is limited by the blue light intensity from the LED and thermal quenching of the phosphor, and the spectrum provides limited emission in regions of the spectrum seen as green/yellow, approximately 560 nm and amber, approximately 590 nm.

Thus, relative to a mercury lamp, commercially available white light LEDs that use a blue light emitting LED combined with a Ce:YAG phosphor, produce significantly weaker emission in the 545 nm and 575 nm regions. For example, at the objective plane of a microscope, output power at 545 nm and 575 nm from such a white light LED was found to be about 10 times lower than the output power from a mercury lamp. This level of power is insufficient for most conventional fluorescence microscopy applications.

By increasing the drive current, some improvement of the light output can be achieved, but fundamentally, the power in this circumstance is limited by the maximum drive current density (i.e. current per unit area) and factors, such as, the LED optical to electrical conversion efficiency, the LED output intensity, the phosphor quantum efficiency, and thermal quenching of both the LED and phosphor, as well as the cooling capacity. Even in the best case, the output from an overdriven air cooled white LED is still 4 to 5 times less than a conventional lamp within the 545 nm and 575 nm spectral range and the lifetime may be significantly reduced by overdriving the device.

The following references provide some other examples of the use of LED sources combined with fluorescent materials or phosphors in other forms.

U.S. Pat. No. 7,898,665 to Brukilacchio et al., issued Mar. 1, 2011, entitled “Light Emitting Diode Illumination System,” for example, discloses a system comprising an arrangement of multiple LEDS that are coupled to a fluorescent rod which emits at a different wavelength to provide sufficiently high brightness illumination for applications such as microscopy or endoscopy. For example a single crystal of Ce:YAG may be pumped by multiple LEDs to generate yellow or amber emission. However, the efficiency of such a device would be limited by total internal reflection due to the high index of refraction of Ce:YAG and requires coupling of multiple LEDs to generate output of sufficient brightness, which increases the cost, size, thermal and electrical requirements.

To provide a more compact and efficient system, the above referenced related copending U.S. Patent application No. 61/651,130, discloses an illumination system that comprises a laser light source, e.g. providing blue light emission in the 440 nm to 490 nm range, for excitation of a wavelength conversion module comprising a wavelength conversion medium, such as Ce:YAG crystal, of a particular shape and size, set in a mounting for thermal dissipation, and an optical concentrator. The shape and size of the wavelength conversion crystal, provides a compact light source with a configuration suitable for applications that require high brightness and narrow bandwidth illumination at a selected wavelength, e.g. for fluorescence microscopy, or other applications requiring étendue-limited coupling or light guide coupling. While effective, due to the particular shape and size of the crystal and cooling requirements, this system is currently relatively costly to manufacture. A solution that is lower cost, compact and provides a broader spectrum is desirable for some applications.

Thus, there is a need for improved or alternative high radiance illumination sources, particularly those that can provide illumination at wavelengths of 545 nm and 575 nm, for example, for fluorescence imaging and analysis applications.

SUMMARY OF THE INVENTION

The present invention seeks to overcome or mitigate one or more disadvantages of known high brightness illumination systems for fluorescence imaging and analysis, or at least provide an alternative.

Thus, one aspect of the present invention provides method of providing high brightness illumination for fluorescence imaging and analysis, comprising: providing a first light source comprising a light emitting device (LED) and a phosphor layer, the LED emitting a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer emitting broadband light emission of longer wavelength comprising light in a wavelength band Δλ_(PHOSPHOR); providing a second light source comprising a laser emitting a second wavelength λ₂, within the absorption band of the phosphor layer; and while operating the LED to generate emission at λ₁ and Δλ_(PHOSPHOR), concurrently optically pumping the phosphor layer with laser emission λ₂ to increase emission intensity in the phosphor emission wavelength band Δλ_(PHOSPHOR).

The method may comprise optically coupling emission comprising λ₁ and Δλ_(PHOSPHOR), along a common optical axis, to an optical output. The method may comprise providing another light source emitting another wavelength λ₃, and optically coupling emission comprising λ₁, Δλ_(PHOSPHOR) and λ₃, along a common optical axis, to an optical output.

By way of example, the LED light source may comprise a standard white light emitting LED light source, i.e. comprising a blue light emitting LED emitting at wavelength λ₁ and a yellow Ce:YAG phosphor layer or coating providing broadband emission over a wavelength band Δλ_(PHOSPHOR). Typically, during normal operation of the blue light emitting LED, the phosphor layer is not saturated by light from the blue LED. Thus, concurrent optical pumping of the phosphor layer with the laser wavelength λ₂, within the absorption band of the Ce:YAG phosphor layer, effectively increases the phosphor emission Δλ_(PHOSPHOR) in the green, yellow and amber regions of the spectrum.

In particular, the supplementary laser optical pumping of the phosphor provides increased optical output over the emission band of the phosphor, so that sufficiently high radiance can be achieved at specific wavelengths, e.g. 545 nm and 575 nm, which are conventionally used for fluorescence imaging and analysis applications.

Another aspect of the present invention provides an illumination system for fluorescence imaging and analysis, comprising: a light source module comprising: a first light source comprising a first light emitting device (LED) and a phosphor layer, the first LED for providing emission at a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer providing broadband light emission of longer wavelength comprising light in a wavelength band Δλ_(PHOSPHOR); a second light source for providing laser emission at a second wavelength λ₂, within the absorption band of the phosphor layer; a controller for driving the first light source to generate emission at λ₁ and Δλ_(PHOSPHOR) and for concurrently driving the laser and optically pumping the phosphor layer with the laser wavelength λ₂, to increase emission in the emission band of the phosphor Δλ_(PHOSPHOR); and optical coupling means for coupling light emission to an optical output of the illumination system.

Thus a laser pumped LED light source unit or module is provided, which has a high radiance output in the emission band of the phosphor Δλ_(PHOSPHOR). The pump laser wavelength λ₂ may be the same as the LED wavelength λ₁, or different from λ₁, provided it is within the absorption band of the phosphor layer. The laser is preferably a solid state laser, e.g. a laser diode, and the control unit provides LED/laser controllers and LED/laser drivers. A suitable choice of phosphor allows for an optical output with high brightness at particular wavelengths, e.g. for applications such as fluorescence imaging and analysis. The phosphor layer may be selected to cover a band within the spectral range from 350 nm to 750 nm and more particularly from 530 nm to 630 nm, i.e. within in the green gap.

In particular, this system provides for high brightness (i.e. high radiance) illumination, e.g. in the 545 nm and 575 nm bands, which are commonly used for fluorescence imaging and analysis, such as, for fluorescence microscopy and for array slide scanners.

The optical coupling means comprises one or more optical elements such as lenses or optical concentrators for focusing the laser emission onto the phosphor layer, collecting emission at λ₁ and Δλ_(PHOSPHOR), and coupling the emission at these wavelengths to the optical output of the light source module.

For example, the optical coupling means comprises an optical element for coupling the laser wavelength λ₂ to the phosphor layer for optical pumping of the phosphor layer and for coupling emission from the first LED and the phosphor layer, comprising λ₁ and Δλ_(PHOSPHOR), to the optical output. Preferably the optical element comprises a dichroic element that acts as a beam-splitter/combiner for coupling the laser wavelength λ₂ onto the phosphor layer for optical pumping of the phosphor layer and for coupling emission from the first LED and the phosphor layer, comprising λ₁ and Δλ_(PHOSPHOR), to the optical output.

If the pump laser wavelength λ₂ is less than the wavelength emission λ₁ of the LED, in a preferred embodiment, the dichroic element has a band edge λ_(D) greater than the laser wavelength λ₂, so that it reflects the laser emission λ₂ and transmits output light emission comprising λ₁ and Δλ_(PHOSPHOR).

As an example, λ₁ comprises emission in the range from 445 nm to 475 nm, i.e. from a blue LED, and Δλ_(PHOSPHOR) covers the emission wavelength range from 500 nm to 750 nm. Preferably Δλ_(PHOSPHOR) covers the emission wavelength range from at least 530 to 630 nm (i.e. the “green gap”), and the pump laser wavelength λ₂ is 450 nm or less.

A dichroic beam-splitter/combiner, having a band edge wavelength λ_(D), between λ₁ and λ₂, may be positioned for reflecting the laser emission λ₂ and transmitting output light emission comprising λ₁ and Δλ_(PHOSPHOR). For example, for wavelength ranges in the example above, if the pump laser wavelength λ₂ is 440 nm, and the blue LED emits λ₁ in the range from 445 nm to 475 nm, the dichroic element has a band edge λ_(D), of 443 nm.

The illumination system may further comprise one or more additional light sources, e.g. at least one of a LED light source providing an emission wavelength λ₃ and an LED light source providing emission at wavelength λ₄. For example, these additional LED light sources are individual LED light sources that provide outputs λ₃ and λ₄ in the near UV and UV spectral regions, respectively. Optical coupling elements are provided to couple outputs at these and other wavelengths, along a common optical axis, to the optical output of the system.

Optical coupling elements may include a second dichroic element, i.e. a dichroic beam-splitter/combiner, for combining outputs λ₃ and λ₄, and then the first dichroic element combines λ₃ and λ₄ with λ₁ and Δλ_(PHOSPHOR). For example, the first LED has an emission band λ₁ in the range between 440 nm and 490 nm and more preferably between 445 nm and 475 nm. The Δλ_(PHOSPHOR) band emitted by the phosphor layer is in the range from 500 nm to 750 nm and more preferably in the range from 530 nm to 630 nm. If the phosphor layer is Ce:YAG as described above, the laser wavelength λ₁ is preferably 450 nm or less, for optical pumping of the phosphor layer. The additional individual LED light sources provide λ₃ comprising near UV emission in the range from 410 nm to 445 nm and λ₄ comprising UV emission in the range from 370 nm to 410 nm or from 350 nm to 390 nm.

In this example, a second dichroic element having a band pass edge wavelength between λ₃ and λ₄, e.g. 409 nm, is used to combine these two wavelengths. Then, if the laser pump wavelength λ₂, and LED emission at λ₃ and λ₄, are all on the short wavelength side of the 443 nm band edge wavelength λ_(D), of the first dichroic element, this element combines λ₃ and λ₄ with λ₁ and Δλ_(PHOSPHOR), along the primary optical axis, to provide an optical output comprising each of these wavelengths.

Optionally the system may comprise one or more additional individual LED light sources and/or one or more additional light source modules for light emission in other spectral bands. For example, additional light sources may provide spectral bands that are in the ultraviolet and near ultraviolet region. These additional sources may comprise, e.g.: a UV LED emitting in the range from 350 nm to 390 nm, e.g. having a peak at 365 nm; or a UV LED emitting in the range from 370 to 410 nm, e.g. having a peak at 385 nm; or a phosphor coated UV LED emitting in the near UV range from 410 nm to 445 nm.

In one embodiment, the at least one additional light source or light source module comprises a LED providing emission at λ₄ and a phosphor layer (Phosphor2) providing a broad emission band Δλ_(PHOSPHOR2). For example, if both λ₁ and Δλ_(PHOSPHOR2) lie on the same side (i.e. the short wavelength side in the example above) of the band edge wavelength λ_(D) of the first dichroic element, the dichroic element combines λ₄ and Δλ_(PHOSPHOR2) with λ₁ and Δλ_(PHOSPHOR); to enable coupling of each of these wavelength bands, along the primary optical axis, to the optical output of the light source unit.

Typically, an optical filtering system within a fluorescence imaging system, such as a fluorescence microscope, provides for further filtering of a selected wavelength band from the output of the illumination system.

If desired, the illumination system may also comprise one or more additional LED light source modules, providing other wavelength bands. It may comprise an additional laser pumped LED light source module, i.e. a second pump laser emitting a wavelength λ₅ within an absorption band of a second phosphor layer (Phosphor2), for optically pumping the second phosphor layer (Phosphor2). A second dichroic beam-splitter/combiner may be provided, having a wavelength edge that is selected to reflect the laser wavelength λ₅ and transmit the emission bands at λ₄ and Δλ_(PHOSPHOR2).

Another aspect of the present invention provides illumination system for fluorescence imaging and analysis, comprising: first and second light source modules and a controller;

the first light source module for providing emission in a first wavelength band, comprising: a first light source comprising a first LED and a first phosphor layer, the first LED providing emission at a first wavelength λ₁ within an absorption band of the phosphor layer and the first phosphor layer providing broadband light emission Δλ_(PHOSPHOR1); a second light source comprising a laser emitting at a second wavelength λ₂, within the absorption band of the first phosphor layer; wherein the controller concurrently drives the first light source to generate emission comprising λ₁ and Δλ_(PHOSPHOR1) and drives the laser for optically pumping the first phosphor layer with the laser wavelength λ₂ to increase emission in the emission band of the phosphor Δλ_(PHOSPHOR1);

the second module for providing emission in a second wavelength band different from the first wavelength band, comprising: a third light source comprising second LED and a second phosphor layer different from the first phosphor layer, the second LED emitting at a wavelength λ₄ within an absorption band of the second phosphor layer and the second phosphor layer providing broadband light emission Δλ_(PHOSPHOR2); a fourth light source comprising a laser emitting at a wavelength λ₅ within the absorption band of the second phosphor layer; wherein the controller concurrently drives the second light source to generate emission comprising λ₄ and Δλ_(PHOSPHOR2) and the laser for optically pumping the second phosphor layer with the laser wavelength λ₅ and the laser wavelength λ₅, to increase emission in the emission band of the second phosphor Δλ_(PHOSPHOR2); and

optical coupling means comprising at least one dichroic beam-splitter/combiner for coupling one or more of λ₁, Δλ_(PHOSPHOR1), λ₄ and Δλ_(PHOSPHOR2), along a common optical axis, to an optical output of the illumination system.

The optical coupling means comprises optical coupling elements such as a coupling lens, an optical concentrator or other optics, and one or more dichroic elements having suitable passband, i.e. dichroic beam-splitters/combiners, to enable the LED light sources and laser light sources to be compactly arranged and for optically coupling the light emission from the LEDs and the phosphor layers to the primary optical axis, aligned to the optical output of the illumination system. The optical coupling elements may comprise dichroic elements for splitting and/or combining emission wavelengths from each light source, as required, and preferably first and second dichroic beam-splitters/combiners having band edges selected for reflecting laser wavelengths λ₂ and λ₅, respectively.

An illumination system, according to preferred embodiments of the invention, has the potential of meeting and exceeding the output of the best arc lamps systems available today at particular wavelengths used for fluorescence microscopy, while overcoming at least some of the limitations of existing high brightness LED light sources.

The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description, taken in conjunction with the accompanying drawings, of preferred embodiments of the invention, which description is by way of example only.

BRIEF DESCRIPTION OF DRAWINGS

In the drawings, identical or corresponding elements in the different Figures have the same reference numeral, or corresponding elements have reference numerals incremented by 100 in successive Figures.

FIG. 1 illustrates schematically an illumination system comprising a light source module according to a first embodiment of the invention;

FIG. 2 illustrates schematically an illumination system comprising a light source module according to a second embodiment;

FIG. 3 shows spectral data for the light source module 100-1 illustrated in FIG. 2, without laser pumping and with laser pumping;

FIG. 4 shows experimental results comparing the optical output power of the light source module illustrated in FIG. 2, with and without laser pumping;

FIG. 5 illustrates schematically an illumination system according to a third embodiment, wherein a light source unit comprises a first light source module similar to that shown in FIG. 2, together with two additional LED light sources;

FIG. 6 illustrates schematically an illumination system according to a fourth embodiment, wherein a light source unit comprises a first light source module similar to that shown in FIG. 2, together with a second light source module;

FIG. 7 shows an output spectrum of the second light source module shown in FIG. 6;

FIG. 8 illustrates schematically an illumination system according to a fifth embodiment wherein the light source unit comprises a first light source module and a second light source module;

FIG. 9 shows the spectral output of the first and second light source modules of FIG. 8: A. without laser pumping of either module, and B. with laser pumping of both modules;

FIG. 10 illustrates schematically an illumination system according to a sixth embodiment, similar to that shown in FIG. 5, except that the pump laser is coupled by a flexible fiber light guide to the first light source unit.

FIG. 11 shows a first arrangement of optical elements for coupling emission of one or more wavelengths, from a light source unit as illustrated in FIG. 5, along a primary optical axis to the optical output of the illumination system;

FIG. 12 shows a second arrangement of optical elements for coupling emission of one or more wavelengths, from a light source unit as illustrated in FIG. 10, along a primary optical axis to the optical output of the illumination system;

FIG. 13 shows three configurations of optical elements for coupling of the pump laser to the phosphor layer of the LED1 using respectively: A. a lens; B. a Compound Parabolic Concentrator (CPC); and C. a taper; and

FIG. 14 shows an arrangement of optical elements for coupling emission of one or more wavelengths, from a light source unit as illustrated in FIG. 4, to an optical input of a fluorescence microscope system, using a liquid light guide.

DESCRIPTION OF PREFERRED EMBODIMENTS

A schematic diagram showing elements of an illumination system 1000, according to a first embodiment of the invention, is shown in FIG. 1. The illumination system 1000 comprises a light source unit or module 100 for providing high brightness illumination for fluorescence illumination and analysis. The light source unit 100 comprises first and second light sources 110 and 120. The first light source 110 comprises an LED 112 (LED1) and a phosphor layer 114, the LED 112 emitting a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer 114 emitting broadband light emission of longer wavelength, comprising light in a wavelength band Δλ_(PHOSPHOR) (abbreviated as Δλ_(P) in the Figures). The second light source 120 comprises a laser 120 emitting at a second wavelength λ₂, also within an absorption band of the phosphor layer. The illumination system 1000 also comprises drive means or drive unit, i.e. controller/driver 180 comprising a power supply 182, LED/laser controller 184 and LED/laser drivers 186, which are coupled by electrical connections 188 for concurrently driving the LED 110 and the laser 120, to enable optical pumping of the phosphor layer 114 with the laser 120, i.e. at the laser wavelength λ₂.

As shown in FIG. 1, in a simple arrangement to provide for laser pumping of the phosphor layer, the first and second light sources 110 and 120 are arranged so that the laser 120 illuminates the phosphor layer 114 at an angle, e.g. at grazing incidence, and emission from the LED112 and the phosphor 114, comprising wavelengths λ₁ and Δλ_(PHOSPHOR), that is emitted along a primary optical axis A, is coupled to an optical output 160 of the system. The laser 120 may be coupled to the phosphor layer through a light guide, an optical concentrator or other optical elements (not shown in FIG. 1).

The first light source 110 may be a phosphor coated LED, mounted on a suitable heatsink for thermal management, e.g. a phosphor LED which provides high brightness white light illumination, i.e. comprising a blue light emitting LED 112 having a deposited phosphor coating 114 providing emission over a desired wavelength band Δλ_(PHOSPHOR) in the longer wavelength visible range. Under normal operation of the first light source 110, even when the LED 112 is driven at higher current or voltage (i.e. the maximum driving current is limited by a maximum driving current density), the phosphor layer 114 is not saturated by the blue light emission from LED 112. Thus, supplementary optical pumping of the phosphor 114, using the pump laser 120, significantly increases the optical output of the phosphor emission band Δλ_(PHOSPHOR). The pump laser wavelength λ₂ may be the same or different from the LED wavelength λ₁, provided it is also within the absorption band of the phosphor layer 114.

Thus, under normal operation, without laser pumping, driving the LED 112 generates light from the LED itself at wavelength λ₁ together with emission in the emission band of the phosphor Δλ_(PHOSPHOR). By concurrently optically pumping the phosphor with the laser wavelength λ₂, the optical output in the emission band of the phosphor Δλ_(PHOSPHOR) is increased significantly, as will be further explained below with reference to FIGS. 2, 3 and 4, and subsequent Figures.

A preferred arrangement for high brightness illumination systems for fluorescence imaging and analysis, comprises two or more light source modules, i.e. providing different output wavelengths, and optical elements for coupling outputs from the two or more light source modules along a primary optical axis to the optical output of the system.

Thus, a schematic diagram showing elements of an illumination system 1000-1, according to a second embodiment of the invention, is shown in FIG. 2. The illumination system 1000-1 comprises a light source unit or module 100-1 for providing high brightness illumination for fluorescence illumination and analysis. The light source unit 100-1 is similar to that shown in FIG. 1, in that it comprises first and second light sources 110 and 120. The first light source 110 comprises an LED 112 (LED1) and a phosphor layer 114, the first LED 112 emitting at a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer 114 emitting broadband light emission of longer wavelength, comprising light in a wavelength band Δλ_(PHOSPHOR) (abbreviated as Δλ_(P) in the Figures). The second light source 120 comprises a laser 120, preferably a solid state laser diode, emitting at a second wavelength λ₂, also within an absorption band of the phosphor layer. Also provided is a dichroic element, i.e. a beam-splitter/combiner, 116 (D1), which reflects the laser wavelength λ₂ to couple the pump laser excitation to the phosphor layer, and transmits λ₁ and Δλ_(PHOSPHOR). That is, for the arrangement shown in FIG. 2, the dichroic beam-splitter/combiner has a band edge λ_(D) between λ₁ and λ₂. Thus the combined emission from the LED 112 and the phosphor 114, λ₁ and Δλ_(PHOSPHOR), is coupled, along the primary optical axis A, to the optical output 160. Optionally, another light source 100-2, i.e. comprising an LED 130 (LED3) emitting another wavelength band λ₃ may be provided and the dichroic beam-splitter/combiner 116 is also used to couple λ₃ to the primary optical axis.

Preferably, other optical coupling elements such as lenses or optical concentrators are also provided for more efficiently coupling the laser emission λ₂ to the phosphor, and for collecting the light emission λ₁+Δλ_(PHOSPHOR), and coupling this light emission, to an optical output 160 of the light source unit 100. However, for simplicity these additional optical elements are not shown in FIG. 2, and they will be described in more detail below with reference to FIGS. 11 to 14. By way of example only, the first light source 110 comprises, a low cost, commercially available “white light” solid state light source i.e. a “white light LED” comprising a phosphor layer 114 pumped by a blue light LED 112, which is manufactured for the demands of general high brightness lighting. One example is a PhlatLight® White LED manufactured by Luminus Devices, which comprises a blue light emitting LED and a Ce:YAG type phosphor coating that provides an emission spectrum, such as illustrated in FIG. 3, spectrum B. The spectrum comprises a strong blue light peak in a first spectral region λ₁ at around 450 nm from LED1 and a broad emission band Δλ_(PHOSPHOR) from 500 nm to 700 nm at longer wavelengths that peaks in the 530 nm to 630 nm region of the spectrum. Thus under normal operation, i.e. when electrically driven at a suitable current and voltage, the resulting light emission, λ₁ and Δλ_(PHOSPHOR), combines to provide a white light spectrum, spectrum B. With supplementary optical pumping by laser 120 at λ₂, i.e. at 440 nm as shown in spectrum C, in the absorption band of the phosphor (spectrum E), the laser pumped emission spectrum shows increased intensity in the broad emission band Δλ_(PHOSPHOR) of the phosphor, as shown by spectrum A. That is, spectrum A comprises emission from LED1 at λ₁ at 445 nm to 475 nm, at a similar intensity as in spectrum B, with a much stronger peak Δλ_(PHOSPHOR) between 500 nm and 750 nm, peaking at around 530 nm to 630 nm.

FIGS. 3 and 4 demonstrate that under normal operation of this phosphor based LED 110, even when driven at higher current or voltage (i.e. the maximum driving current is limited by a maximum driving current density), the phosphor layer 114 is not saturated by the blue light emission from LED 112. Thus, supplementary optical pumping of the phosphor 114 using the pump laser 120 significantly increases the optical output Δλ_(PHOSPHOR) from the phosphor at longer wavelengths, as shown by comparing the emission spectra A and B, in FIG. 3. In particular, by selecting an appropriate phosphor LED 110, having a phosphor emission in the 500 nm to 700 nm range, and preferably having a peak in the range from 530 to 630 nm, high brightness illumination can be provided at these wavelengths, i.e. even within the green gap.

FIG. 4 shows the optical output of light source module 100-1 as a function of LED drive current with and without supplementary laser optical pumping of the phosphor layer. That is, FIG. 4 compares the optical power at the objective plane of a fluorescence imaging system, when operating the white light LED with and without laser pumping, using a 40× objective and an excitation filter to provide an illumination band from 545 nm to 575 nm. For operation at the maximum driving current, with laser pumping, the output of the light source unit 100 in this wavelength band was increased 2-3 times at the maximum driving current, compared to operation of the same white light phosphor LED 110 without supplementary laser pumping of the phosphor layer.

Thus, by way of example, the light source module 100-1 for illumination system 1000-1 comprises a first light source 110 comprising the LED1 112 emitting λ₁ in the range 445 nm to 475 nm having a phosphor 114 emitting Δλ_(PHOSPHOR) in the range 500 nm to 750 nm, which is pumped by the second light source 120 comprising the laser emitting λ₂ at 440 nm. The band edge wavelength λ_(D) of the dichroic element is selected at 443 nm, i.e. between λ₁ and λ₂, and arranged to reflect the laser wavelength λ₂, and transmit λ₁ and Δλ_(PHOSPHOR). Thus, the optical output of the illumination module 100 comprises λ₁+Δλ_(PHOSPHOR).

Referring again to FIG. 2, optionally, if it is required to provide another light source 100-2, i.e. comprising an LED 130 (LED3) emitting another wavelength band λ₃, the dichroic beam-splitter/combiner 116 provides a compact and convenient way to couple light of wavelength λ₃ from LED 130 to the primary optical axis. As illustrated, the dichroic beam-splitter/combiner 116 has a pass band edge selected to reflect the laser emission at the laser wavelength λ₂, and transmit emission at λ₁ from the LED 110 and Δλ_(PHOSPHOR) from the phosphor, and also reflect λ₃, the output emission comprises λ₁ and Δλ_(PHOSPHOR) and λ₃. Thus, the combined optical output λ₁+Δλ_(PHOSPHOR), and optionally λ₃, of the illumination system can be coupled to the optical input of a fluorescence imaging and analysis system, such as a slide scanner or fluorescence microscope, with suitable coupling optics (not shown in FIG. 2, see FIGS. 11 to 14). As is conventional, filters within the fluorescence imaging system provide for selection of appropriate wavelengths for broadband or narrowband illumination, e.g. standard wavelength bands for fluorescence analysis, just as they would be if a conventional lamp illumination system was used. Beneficially, the solid state illumination system of the embodiment not only provides high radiance illumination at selected wavelengths, but also provides other advantages of solid state light sources over conventional lamps, i.e. electronic control of illumination parameters, such as, intensity and pulse duration.

An illumination system 2000 according to a third embodiment is shown in FIG. 5. The light source unit 200 comprises a first light source module 100-1, comprising first and second light sources 110 and 120, identical to module 100-1 shown in FIG. 2. Like parts are labeled with the same reference numerals in each Figure. Additionally, a second light source module 100-2 comprises two additional light sources 100-2 and 100-3, i.e. a LED or LED arrays 130 and 140 for light emission at other wavelengths. A second dichroic element, i.e. beam-splitter/combiner 118 is provided, which has a band edge selected to combine the output of LED3 and LED4. That is, a LED 130 (LED3) provides light emission at λ₃, and a LED 140 (LED4) provides light emission at wavelength λ₄. For example, LED3 and LED4 may provide near ultraviolet (near UV) emission and UV emission respectively.

The drive system 180 is similar to that shown in FIG. 1, comprising a power supply 182, LED/laser controller 184 and LED/laser drivers 186 for driving each of the LED light sources, i.e. LEDs 110, 130 and 140 and laser 120. The additional dichroic element 118 is provided for coupling the output from the third and fourth light sources 130 and 140, and then combining other wavelengths, via the first dichroic element 116, along the primary optical axis, to couple each of the combined wavelengths, λ₁, Δλ_(P), λ₃ and λ₄, to the output 160 of the light source unit 200.

For example, the first light source 110 may comprise a blue light emitting LED 112 emitting a wavelength λ₁ in the range from 445 nm to 475 nm, with a phosphor layer 114 emitting in Δλ_(PHOSPHOR) in the 530 nm to 630 nm band. The second light source 120 comprises a laser emitting at λ₂, i.e. at 440 nm in the absorption band of the phosphor layer 114, and the dichroic element 116 has a 443 nm edge, i.e. as described with respect to the light source unit 100-1 shown in FIG. 2. To provide a combined UV/near UV illumination band, LED 130 comprises a near UV LED (LED3) providing near UV emission at λ₃, e.g. 410 nm to 445 nm, and LED 140 comprises a UV LED (LED4) providing UV emission at λ₄, e.g. 370 nm to 410 nm or 350 nm to 390 nm. In the configuration illustrated in FIG. 5, the second dichroic element 118 is provided which has a band edge to reflect the shorter wavelength UV emission at λ₄ from LED4 and transmit the longer wavelength emission λ₃ from LED3. The emission λ₃+λ₄ is reflected by the first dichroic element 116 and redirected to the optical output 160. That is, LED3 and LED4 can cover wavelengths in the near UV and UV bands which are reflected by the first dichroic element 116, i.e. wavelengths shorter than the 443 nm band edge. Thus, the illumination system 2000 provides for high brightness illumination covering the UV, near UV, blue, green, yellow and red, to the near infrared regions. With suitable choices of λ₁, λ₂, Δλ_(PHOSPHOR), λ₃, λ₄, the system can provide sufficient intensity at each wavelength commonly used for fluorescence imaging and analysis.

An illumination system 3000 according to a fourth embodiment is shown in FIG. 6. This system comprises a first light source module 100-1 identical to unit 100-1 shown in FIG. 2 and module 100-1 shown in FIG. 5. Thus, it comprises a first light source 110 comprising LED 112 (LED1) and its phosphor layer 114 (Phosphor1) and a second light source comprising the pump laser 120, providing output emission at λ₁ and Δλ_(P1). The second light source 100-2 module comprises a LED 140 (LED4) and a different phosphor layer 124 (Phosphor2). For example, to provide a UV and near UV band, LED 4 comprises a UV LED, providing UV emission λ₄ at 370-410 nm or 350-390 nm, for exciting Phosphor2. Phosphor2 provides a near UV emission band, Δλ_(P2), e.g. 410-445 nm. A sample emission spectrum of the second illumination module, comprising λ₄ and Δλ_(P2), is shown in FIG. 7. As explained with reference to FIG. 5, since λ₄ and Δλ_(P2) are shorter than the 443 nm band edge of the dichroic element 116, they will be reflected and redirected to the optical output 160 of the illumination unit.

An illumination system 4000 according to a fifth embodiment is shown in FIG. 8. An illumination unit 400 comprises first and second illumination modules 100-1 and 100-2. The first illumination module 100-1 is identical to module 100-1 illustrated in FIGS. 2 and 5. The second illumination module 100-2 is a similar laser pumped phosphor LED, i.e. phosphor LED 130, comprising LED 140 (LED4) emitting λ₄, phosphor layer 124 (Phosphor2) emitting Δλ_(P2), and a pump laser 150 emitting laser wavelength λ₅. In this embodiment, to provide a UV and near UV band and λ₄ and Δλ_(P2), the light source module 100-2 comprises LED4 emitting in a UV band, e.g. 375-410 within an absorption band of Phosphor2, and Phosphor2 emitting in the near UV band, e.g. 410-445 nm. The dichroic element 118 is positioned to reflect the pump laser emission at λ₅ and transmit the LED4 emission at λ₄. That is, second dichroic element 118 has a passband edge between the LED5 laser wavelength λ₅ and the LED4 wavelength λ₄, e.g. 373 nm. The resulting output emission spectrum of system 4000 is shown in FIG. 9: spectrum A: without laser pumping of light source module 100-1 or 100-2; and spectrum B: with laser pumping of both modules 100-1 and 100-2. These spectra demonstrate the significant increase in emission intensity of both Phosphor 1 and Phosphor2 emission, with laser pumping.

An illumination system 5000 according to a fifth embodiment, comprising a light source unit 500 is illustrated in FIG. 10. This system is similar to that shown in FIG. 5, and all like components are labeled with the same reference numerals. This embodiment differs from that shown in FIG. 5 in that the pump laser 120 (Laser2) is housed within the control unit 180 instead of within the light source unit 500. The output of the pump laser is coupled by a flexible light guide 190 to an input 162 of the light source unit 500, and then directed by the dichroic element 116 for pumping of the phosphor layer 114.

In each of the embodiments described above, the pump laser system 120 may comprise a solid state laser, e.g. a single laser diode or a laser diode array. Each LED light source may comprise a single LED or a LED array. The phosphor layer for LED1 is integrated with LED1, i.e. a direct die contact layer or coating deposited on LED1, or a phosphor suspended in an encapsulant such as silicon, also in direct contact with LED1. The Phosphor2 layer for LED4 is similarly integrated with LED4. In a variation of the module 100-2 shown in FIG. 6, Phosphor1 or Phosphor2 may be a remote phosphor layer, e.g. a phosphor coating on a separate substrate, pumped by (non-laser) LED1 or LED4. While specific arrangements of dichroic elements, i.e. beam-splitters and combiners, have been described it will be appreciated that other arrangements of these elements can be provided. In particular the wavelengths of each light source element may be combined or split by suitable choices of the bandpass or band edge of each dichroic element.

To simplify optical coupling, it is preferable that each dichroic element is selected to reflect the pump laser wavelengths, i.e. λ₂ or λ₅, in the embodiments described above. Additionally, to provide for effective optical coupling of the pump laser to the phosphor layer and efficient collection of the light emission from each light source, optical coupling elements such as lenses or optical concentrators are used. For simplicity these elements are not shown in the preceding Figures. FIGS. 11 to 14 show further details for arrangements of these optical coupling elements, by way of example.

FIG. 11 shows an arrangement of optical coupling elements for the system illustrated in FIG. 5. Like parts are labeled with the same reference numerals. For thermal management, the phosphor LED 110 comprising LED 112 (LED1) and phosphor layer 114 is mounted on a copper plate 119 which is cooled by water or forced air. Focusing and collection optics comprise lens 122, which collects light emission from the pump laser 120. The pump laser light λ₂ is reflected from dichroic element 116, and collected by collection lens 124 to focus the pump laser light λ₂ onto the phosphor layer 114. Light emission at λ₁ and Δ_(PHOSPHOR) is collected by collection lens 124, transmitted by the dichroic element 116 and collimated by output coupling lenses 126 for coupling to the optical output 160 of the illumination system, e.g. to an optical input of a fluorescence imaging and analysis system or to an optical input of a microscope (not shown). Emission from the LEDs 130 and 140 is collected by lenses 132 and 142, respectively, and coupled through the second dichroic plate 118, the first dichroic plate 116 and the output coupling lenses 126 to the optical output 160.

FIG. 12 shows an arrangement of optical coupling elements for a system such as illustrated in FIG. 10. This arrangement is similar to that shown in FIG. 8, except that the pump laser 120 is housed externally of the light source unit, for example within the control unit 180 as shown in FIG. 8, and the pump laser radiation is coupled to an input 162 of the light source unit 500 via a flexible optical light guide 190.

FIGS. 13 A, B and C show three variants of the arrangement of optical coupling elements shown in FIG. 10. In FIG. 13B the coupling lens 124A of FIG. 13A is replaced by a compound parabolic concentrator 124B, and in FIG. 13C a conical tapered concentrator 124C is used. Other optical coupling elements are similar to those shown in FIG. 11.

In another variant of the optical coupling elements, shown in FIG. 14, the optical emission transmitted or reflected towards the optical output is collected by output coupling lens 126 and focused onto the input of an optical light guide 192, which may be a liquid light guide, for coupling to an input coupling lens 128 of a fluorescence imaging system, such as a fluorescence microscope or slide scanner. Again, other optical coupling elements are similar to those shown in FIG. 11 and are labeled with like reference numerals.

In summary, a solid state high radiance illumination source as disclosed herein is capable of providing for high intensity illumination at each of a number of wavelengths commonly used for fluorescence analysis and imaging. The laser pumped LED and arrangement of optical components provide for a compact light source unit that may comprise one or more individual LED light sources or LED light source modules, providing different wavelength outputs. The system provides an alternative to conventional arc lamps, and addresses limitations of other available solid state LED light sources to provide high brightness at selected wavelengths, particularly in the 530 nm to 630 nm range.

The high radiance solid state illumination system also provides advantages over conventional lamp illumination sources, for example, allowing for electronic control of intensity and pulse generation as disclosed in copending PCT International patent application no. PCT/CA2012/00446 entitled “Light Source, Pulse Controller and Method for Programmable Pulse Generation and Synchronization of Light Emitting Devices”.

Although embodiments have been described in detail above by way of example, it will be apparent that modifications to the embodiments may be made. For example, each LED light source referred to as a LED, and it is apparent that each may be a single LED or an LED array of multiple LED, and the phosphor layer may be directly coated on the emitter surface of the LED or LED array, or provided as an overlying phosphor containing layer. For simplicity single optical elements such as lenses are illustrated, but compound lens or other suitable coupling optics may be used. It will also be apparent that additional LED light sources may be added and similarly optically coupled to the optical output using optical coupling elements comprising dichroic beam-splitter/combiners. However, to reduce reflective and transmissive losses, and reduce size and cost, it may desirable to provide a simple design with fewer components.

Although embodiments of the invention have been described and illustrated in detail, it is to be clearly understood that the same is by way of illustration and example only and not to be taken by way of limitation, the scope of the present invention being limited only by the appended claims. 

1. A method of providing high brightness illumination for fluorescence imaging and analysis, comprising: providing a first light source comprising a light emitting device (LED) and a phosphor layer, the LED emitting a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer emitting broadband light emission of longer wavelength comprising light in a wavelength band Δλ_(PHOSPHOR); providing a second light source comprising a laser emitting a second wavelength λ₂, within the absorption band of the phosphor layer; and while operating the LED to generate emission at λ₁ and Δλ_(PHOSPHOR), concurrently optically pumping the phosphor layer with laser emission λ₂ to increase emission intensity in the phosphor emission wavelength band Δλ_(PHOSPHOR).
 2. A method according to claim 1, further comprising optically coupling emission comprising λ₁ and Δλ_(PHOSPHOR), along a common optical axis.
 3. A method according to claim 1, further comprising providing another light source emitting another wavelength λ₃, and optically coupling emission comprising λ₁, Δλ_(PHOSPHOR) and λ₃, along a common optical axis.
 4. An illumination system for fluorescence imaging and analysis, comprising: a light source module comprising: a first light source comprising a first light emitting device (LED) and a phosphor layer, the first LED for providing emission at a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer providing broadband light emission of longer wavelength comprising light in a wavelength band Δλ_(PHOSPHOR); a second light source for providing laser emission at a second wavelength λ₂, within the absorption band of the phosphor layer; a controller for driving the first light source to generate emission at λ₁ and Δλ_(PHOSPHOR) and for concurrently driving the laser and optically pumping the phosphor layer with the laser wavelength λ₂, to increase emission in the emission band of the phosphor Δλ_(PHOSPHOR); and optical coupling means for coupling light emission to an optical output of the illumination system.
 5. The illumination system of claim 4 wherein the optical coupling means comprises at least one optical element for coupling the laser wavelength λ₂ to the phosphor layer for optical pumping of the phosphor layer and for coupling emission from the first LED and the phosphor layer, comprising λ₁ and Δλ_(PHOSPHOR), to the optical output.
 6. The illumination system of claim 4 wherein the optical coupling means comprises a dichroic element having a band edge for reflecting the laser wavelength λ₂ onto the phosphor layer for optical pumping of the phosphor layer and for transmitting emission from the first LED and the phosphor layer, comprising λ₁ and Δλ_(PHOSPHOR), to the optical output.
 7. The illumination system of claim 4, further comprising another light source comprising an LED emitting at a third wavelength λ₃, and wherein the optical coupling means couples light emission comprising λ₁, Δλ_(PHOSPHOR) and λ₃, along a common optical axis to the optical output of the illumination system.
 8. The illumination system of claim 4, further comprising another light source comprising an LED emitting at a third wavelength λ₃, wherein the optical coupling means comprises a dichroic optical element having a band edge for reflecting the laser wavelength λ₂ onto the phosphor layer for optical pumping of the phosphor layer, for transmitting emission from the first LED and the phosphor layer, comprising λ₁ and Δλ_(PHOSPHOR), and further for reflecting the third wavelength λ₃, for optically coupling light emission, comprising λ₁, Δλ_(PHOSPHOR) and λ₃, along a common optical axis to the optical output of the illumination system.
 9. The illumination system of claim 8, further comprising yet another light source emitting at a fourth wavelength λ₄ and wherein the optical coupling means further comprises a second dichroic element for coupling emission comprising λ₃ and λ₄, via the first dichroic element, along the common optical axis to the optical output of the illumination system, the second dichroic element having a band edge between λ₃ and λ₄.
 10. The illumination system of claim 4, further comprising another light source comprising and LED emitting at a fourth wavelength λ₄ and a second phosphor layer (Phosphor2) emitting a wavelength band Δλ_(PHOSPHOR2), and wherein the optical coupling means couples light emission comprising λ₁, Δλ_(PHOSPHOR), λ₄ and Δλ_(PHOSPHOR2), along a common optical axis, to the optical output of the illumination system.
 11. The illumination system of claim 10, wherein the optical coupling means comprises a dichroic element having a pass band λ_(D) selected to reflect the laser wavelength λ₂, and transmit λ₁ and Δλ_(PHOSPHOR), wherein λ₄ and Δλ_(PHOSPHOR2) are also reflected by the dichroic element, and wherein the dichroic element is positioned for coupling light emission comprising λ₁, Δλ_(PHOSPHOR), λ₄ and Δλ_(PHOSPHOR2), along the common optical axis, to the optical output of the illumination system.
 12. The illumination system of claim 4, further comprising a second light source module, the second light source module comprising: a third light source comprising another light emitting device (LED) and a second phosphor layer, the other LED providing emission at a fourth wavelength λ₄ within an absorption band of the second phosphor layer (Phosphor2) and the phosphor layer providing broadband light emission of longer wavelength comprising light in a wavelength band Δλ_(PHOSPHOR2); a fourth light source providing laser emission at a fifth wavelength λ₅, within the absorption band of the second phosphor layer; the controller further providing for driving the third light source to generate emission at λ₄ and Δλ_(PHOSPHOR2) and driving the fourth light source for concurrently optically pumping the second phosphor layer with the laser wavelength λ₅, to increase emission in the emission band of the phosphor Δλ_(PHOSPHOR2); and optical coupling means for coupling light emission comprising λ₄ and Δλ_(PHOSPHOR2) to the optical output of the illumination system.
 13. The illumination system of claim 12 wherein the optical coupling means comprises: a first dichroic element for coupling the laser wavelength λ₂ for optically pumping the first phosphor layer and coupling emission comprising λ₁ and Δλ_(PHOSPHOR) from the LED and the phosphor layer of the first module, along a primary optical axis to the optical output, and a second dichroic element for coupling the laser wavelength λ₅ for optically pumping the second phosphor layer and coupling emission comprising λ₄ and Δλ_(PHOSPHOR2) from the other LED and the second phosphor layer, via the first dichroic element, along the primary optical axis to the optical output.
 14. The illumination system of claim 12 wherein the optical coupling means comprises: a first dichroic element having a band edge for reflecting the laser wavelength λ₂ along a primary optical axis for optically pumping the first phosphor layer and transmitting emission along the primary optical axis, comprising λ₁ and Δλ_(PHOSPHOR), from the LED and the phosphor layer of the first module, and a second dichroic element having a band edge for reflecting the laser wavelength λ₅ along a secondary optical axis for optically pumping the second phosphor layer and transmitting emission along the secondary optical axis, comprising λ₄ and Δλ_(PHOSPHOR2), from the other LED and the second phosphor layer, and the first dichroic element also reflecting emission transmitted by the second dichroic element, comprising λ₄ and Δλ_(PHOSPHOR2), along the primary optical axis to the optical output.
 15. The illumination system of claim 4 wherein the second light source comprises a solid state laser integrated within the first light source module.
 16. The illumination system of claim 12 wherein the fourth light source comprises a solid state laser integrated within the second light source module.
 17. The illumination system of claim 4 wherein the second light source comprises a laser light source housed within a unit of the controller which is coupled by a light guide to the light source module for providing optically pumping the first phosphor layer with laser emission λ₁.
 18. The illumination system of claim 12 wherein the second light source comprises a laser light source, housed within a unit of the controller, which is coupled by a light guide to the light source module for optically pumping the second phosphor layer with laser emission λ₅.
 19. The illumination system of claim 4 wherein λ₁ comprises emission in the range from 440 nm to 490 nm and Δλ_(PHOSPHOR) comprises emission in the range from 500 nm to 750 nm.
 20. The illumination system of claim 4 wherein λ₁ comprises emission in the range from 445 to 475 nm and Δλ_(PHOSPHOR) is in the range from at least 530 nm to 630 nm.
 21. The illumination system of claim 4 wherein Δλ_(PHOSPHOR) covers the emission wavelength range from at least 530 nm to 630 nm.
 22. The illumination system of claim 21 wherein the pump laser wavelength λ₂ is one of: 450 nm or less; 440 nm or less; less than λ₁.
 23. An illumination system according to claim 21 wherein the wavelength λ₁ emitted by the first LED is in the range between 445 nm and 475 nm; and the wavelength λ₂ of the pump laser is 445 nm or less.
 24. The illumination system of claim 7 wherein the emission wavelength λ₃ comprises light emission in at least one of the ultraviolet and near ultraviolet spectral regions.
 25. The illumination system of claim 9 wherein the emission wavelengths λ₃ and λ₄ comprise light emission in the near ultraviolet and ultraviolet spectral regions.
 26. An illumination system according to claim 12 wherein the spectral band phosphor layer Δλ_(PHOSPHOR2) is in the range from 410 nm to 445 nm and wherein the wavelength λ₅ of the second laser is in the range from 370 nm to 410 nm or from 350 nm to 390 nm.
 27. An illumination system according to claim 7 wherein the emission wavelength λ₃ of the other light source comprises a wavelength shorter than λ₁, and the other light source comprises one of a narrow band UV LED, a LED providing emission at 440 nm, 365 nm and/or 385 nm, and a phosphor coated UV LED providing broadband near UV emission.
 28. An illumination system according to claim 14 wherein each of the laser pump wavelength λ₂ and emission wavelengths λ₃ and λ₄, are on the short wavelength side of the band edge wavelength λ_(D) of the first dichroic element.
 29. An illumination system for fluorescence imaging and analysis, comprising: first and second light source modules and a controller; the first light source module for providing emission in a first wavelength band, comprising: a first light source comprising a first LED and a phosphor layer, the first LED providing emission at a first wavelength λ₁ within an absorption band of the phosphor layer and the phosphor layer providing broadband light emission Δλ_(PHOSPHOR); a second light source comprising a laser emitting at a second wavelength λ₂, within the absorption band of the phosphor layer; wherein the controller concurrently drives the first light source to generate emission comprising λ₁ and Δλ_(PHOSPHOR) and the laser for optically pumping the phosphor layer with the laser wavelength λ₂ to increase emission in the emission band of the phosphor Δλ_(PHOSPHOR); a second module for providing emission in a second wavelength band different from the first wavelength band; a third light source comprising second LED and a second phosphor layer different from the first phosphor layer, the second LED emitting at a wavelength λ₄ within an absorption band of the second phosphor layer and the second phosphor layer providing broadband light emission Δλ_(PHOSPHOR2); a fourth light source comprising a laser emitting at a wavelength λ₅ within the absorption band of the second phosphor layer; wherein the controller concurrently drives the second light source to generate emission comprising λ₄ and Δλ_(PHOSPHOR2) and the laser for optically pumping the second phosphor layer with the laser wavelength λ₅ and the laser wavelength λ₅, to increase emission in the emission band of the second phosphor Δλ_(PHOSPHOR2); optical coupling means comprising at least one dichroic beam-splitter/combiner for coupling one or more of λ₁, Δλ_(PHOSPHOR1), λ₄ and Δλ_(PHOSPHOR2), along a common optical axis, to an optical output of the illumination system.
 30. An illumination system according to claim 29 wherein the optical coupling means further comprises optical coupling elements comprising at least one of a focusing/collection lens, an optical concentrator and an output coupling lens. 